DE102005016783A1 - Sheet braking device for use in printing machine has sheet support of blowing apparatus contains nozzle areas having air nozzles - Google Patents

Abstract

The sheet support (10) of a blowing apparatus (12) contains the nozzle areas having the air nozzles. The blowing air volumetric flow of one air nozzle in one nozzle area is smaller than the blowing air volumetric flow of other air nozzle in other nozzle area. An independent claim is also included for a printing machine.

Description

The The present invention relates to a sheet brake for braking from sheets of substrate, with circulating brake elements and at least a sheet support, which is arranged between the brake elements and a blowing device forms, according to the preamble of claim 1.

A such sheet brake is, for example, on page 1-19 of Operating manual-Airglide issued by MAN Roland Druckmaschinen AG for the Printing machine Roland 700 shown. Unfavorable on this sheet brake is that the blown air volume flow the blowing device must be adjusted by means of a valve. This setting must be dependent from the basis weight of the bow. From print job to print job changing surface weight the setting needs to be pretty common be made. Therefore, the set-up time is high. Besides, waste can accumulate and can smear paint from the bow to the blower, if an incorrect value has been set. The blowing device must be cleaned to free them from the lubricated paint. As a result, the maintenance time increases.

The EP 1 184 173 A2 which forms further state of the art, can not make an effective contribution to solving the problems mentioned. In this patent application, a sheet guiding device is described, at the risk of contact points throttled air nozzles are arranged.

Therefore The invention is based on the object, a user-friendly To create sheet brake.

These Task is by a sheet brake with the features of the claim 1 solved.

The sheet brake according to the invention for braking sheets of substrate, with circulating brake elements and at least one arch support, which is arranged between the brake elements and a blowing device forms, is characterized in that the sheet support a first nozzle field with air nozzles and a second nozzle field with air nozzles includes, and that the air nozzles of the first nozzle field are designed to generate blown air volume flows, the smaller as blowing air volume flows of the air nozzles of the second nozzle field are.

at The sheet brake according to the invention is none of the basis weight the bow dependent setting the blower required. This reduces set-up time. The high functional reliability is not only independent of the basis weight of the sheet, but also independent guaranteed by the machine speed. In the sheet brake according to the invention unnecessary settings that serve to change the blown air to adapt to the machine speed. The sheet brake according to the invention But it is not only very easy to use, but also very much easy to maintain. Greasing the paint from the bow to the arch support will in all circumstances avoided, so a frequent Cleaning the arch support is not required. As a result, the waste also decreases.

In the dependent claims mentioned developments are briefly explained below.

at a development are the air nozzles of the second nozzle field less than the air jets of the first nozzle field throttled. Accordingly acts It is true that both the air nozzles of the second nozzle field as well as the air nozzles of the first nozzle field around throttled air nozzles, d. H. air nozzles with integrated air throttles (throttle nozzles) or air nozzles with upstream air throttles, but the throttling effect of Air throttling of the second nozzle field less than the throttle effect of the air throttles of the first nozzle field. This Difference in terms the throttling effect can z. B. be realized by the air throttles of the second nozzle field each have less vortex chambers than the air nozzles of first nozzle field.

A further development has the content that the air nozzles of the first nozzle array and the air nozzles of the second nozzle array are associated with labyrinth-like air throttles for generating the different blown air volume flows. The labyrinthine air throttles can each have a z. Example, by a bed, by a spiral air duct, by projecting Luftwehrre or by perforated plates formed labyrinth. With regard to the formation of said labyrinth forms is the EP 1 184 173 A2 (see therein 4 . 6a to 8th and related parts of the description) are incorporated in the description of the present invention (incorporation by reference). Regarding the labyrinthine formation of the air throttles is the DE 44 06 739 A1 also included in the description of the present invention (incorporation by reference).

In a further development, the first nozzle field is arranged more centrally and the second nozzle field more decentralized with respect to the sheet support. The second nozzle field is thus closer to Edge of the nozzle fields having nozzle surface of the sheet support as the first nozzle array. Said edge is particularly at risk of smearing the color of the sheet and therefore protected by the larger blowing air flow rates of the second nozzle array in an optimal manner against the greasing. The risk of greasing is much lower in the central region of the nozzle surface, so that there the smaller blown air flow rates of the first nozzle array for the formation of a sheet without contact supporting air cushion are sufficient. The fact that the blown air volume flows are smaller in the first nozzle field, it is ensured that the blowing device, the deposition behavior of the sheet, even if it has the lowest possible weight per unit area, not deteriorated by too much air below the sheet or does not lift the sheet from the rotating brake elements. During the braking time, the contact between the brake elements and the arc to be braked is ensured.

According to one Further development is the first nozzle array of the second nozzle array annular surround. Accordingly forms the second nozzle field a circular, oval or polygonal ring around the first nozzle array runs around. This Ring may break at one or more points, e.g. B. in the form of nozzle-free Areas have.

According to one Further development is the nozzle surface of the arch support arched. This vault is present only at the peripheral edge of the nozzle surface and that of this edge curvature enclosed part of the nozzle surface is plan.

According to one Further development, the sheet support nozzle field-wise divergent from each other nozzle densities on. This means that the air nozzles in the first nozzle field in another of air nozzle to adjacent air nozzle nozzle distance to be measured are arranged as the air nozzles in another nozzle field the nozzle surface, z. In the second nozzle field or in a third nozzle field. Preferably, the nozzle density decreases from the center of the nozzle surface to the latter Edge towards.

at Another development are the arch support and another such arch support arranged in a row between the brake elements. The sheet brake So hereby includes a variety of arch supports that are identical to each other and are formed differently from the brake units. The arch supports are close to each other and arranged between two of the brake elements.

The according to the invention or one the developments trained accordingly sheet brake is preferably Part of a sheet delivery and the latter is preferably Component of a printing press, preferably a perfector printing press.

Further provide functionally and structurally advantageous developments from the following description of a preferred embodiment and the associated Drawing.

In this shows:

1 a printing press with a sheet delivery including a sheet brake,

2 a three-dimensional representation of arch supports and brake units of the sheet brake 1 .

3 a top view of one of the arch supports 2 and

4 a sectional view of throttle nozzles of the sheet support 3 ,

In 1 is a machine 1 for processing bows 2 shown from printing material. The machine 1 is a printing press and includes a printing unit 3 for lithographic offset printing and a sheet delivery 4 with a chain conveyor 5 , Preferably, the machine comprises 1 several such printing units and is it a perfector printing machine for printing on both sides of the sheet. Under the chain conveyor 5 is a sheet brake 6 arranged, which the bow 2 before filing on a pile of sheets 7 decelerating.

In 2 is shown that the sheet brake 6 only two modular braking units 6.1 . 6.2 includes, depending on the format of the bow 2 and are continuously adjustable from the position of their pressure-free corridors on the sheet edge. In this positioning, the brake units 6.1 and 6.2 along a common drive shaft 8th shifted relative to each other.

Every brake unit 6.1 . 6.2 includes two pulleys 9 , a vacuum-loaded suction chamber and as a circulating brake element at least one endless brake band 11 , by which a brake belt is understood. The brake band 11 runs around the pulleys 9 and the internal drive shaft 8th and is fricatively driven by the latter.

Furthermore, the sheet brake includes 6 several identical arch supports 10 , by the operator either between the brakes units 6.1 . 6.2 can be inserted by means of quick fasteners. The number of arch supports to be inserted 10 depends on the sheet format of the respective print job and therefore on the distance between the brake units 6.1 . 6.2 to each other. As a rule, there are several arch supports 10 in use and make this one to the drive shaft 8th parallel row. The existing between the brake units in the respective sheet format gap 6.1 . 6.2 should by means of the arch supports 10 as well as possible it will be completed. Therefore, in any case, a clearance or a distance between the respective brake unit 6.1 or 6.2 and the closest to this brake unit arch support 10 to measure is less than 15 centimeters and is one of arch support 10 to adjacent arch support 10 distance to be measured less than 5 centimeters. According to 2 are the arch supports 10 arranged on impact, so that the last-mentioned distance is practically zero.

The arch supports 10 are periodically pressurized with compressed air and together form a blowing device 12 that the bow to be braked 2 bears during the braking contactless by means of an air cushion. The air cushion is between a nozzle surface 20 the respective arch support 10 and the bow 2 generated and is in the transport cycle of the incoming bow 2 activated. This is the blowing device 12 connected to the compressed air source and the latter is cyclically switched on and off.

Each nozzle surface 20 is rounded at its edge downwards, this convex curvature contributes to a smearing of the ink from the bottom of the double-sided printed sheet 2 to the nozzle surface 20 to prevent. Said curvature is in the form of a convex rounding of the circumferential edge of the nozzle surface 20 formed, which rounding respect 3 runs perpendicular to the image plane. In contrast to this rounding, which in 3 can not be seen, is a running in the image plane rounding of the corners of the nozzle surface 20 clearly visible.

It is also in 3 by means of various hatching drawings indicated that the nozzle surface 20 in a first nozzle field 13 , a second nozzle field 14 and a third nozzle field 15 is subdivided. The nozzle fields 13 to 15 are mirror-symmetrical with respect to a running direction LR of the bow 2 extending center axis of the arch support 10 arranged. The third nozzle field 15 has an oval shape and is in the center of the nozzle area 20 arranged. The second nozzle field 14 is at said convex rounded edge of the nozzle surface 20 arranged. The first nozzle field 13 is between the inner, third nozzle field 15 and the outer, second nozzle array 14 arranged. The first nozzle field 13 and the second nozzle field 14 are each annular.

The nozzle density, ie the number of nozzles per unit area, is in the third nozzle field 15 less than in the other two nozzle fields 13 . 14 ,

Each of the three nozzle fields 13 to 15 includes a variety of throttled air nozzles 16 . 17 , Wherein blown air volume flows VS1, VS2 (see. 4 ) of the air nozzles 16 . 17 in the third nozzle field 15 lowest, in the second nozzle field 14 highest and in the first nozzle field 13 although higher than in the third nozzle field 15 , but lower than in the second nozzle field 14 are measured. The size of the blown air volume flows VS1, VS2 thus decreases from the center of the arch support 10 towards the periphery, field by field. In this case, for example, with the first blown air volume flow VS1 of the first nozzle field 13 an average blown air volume flow in the first nozzle field 13 arranged air nozzles 16 meant and it is not excluded that some of the first nozzle box 13 arranged air nozzles 16 with respect to their blown air volume flow slightly deviate from said average value.

In 4 is based on the first and second nozzle field 13 . 14 a technical realization of the staggering of different sized blown air volume flows VS1, VS2 shown. It is an imaginary dividing line 21 indicated, which the first nozzle field 13 with the air nozzle 16 from the second nozzle field 14 with the air nozzle 17 separates. The air nozzles 16 . 17 are labyrinthine air throttles 18 upstream, over which the air nozzles 16 . 17 be subjected to the compressed air. The air throttle 18 the air nozzle 16 of the first nozzle field 13 has more vortex chambers 19 and therefore a stronger throttling effect than the air nozzle 17 of the second nozzle field 14 , In the example shown has the air throttle 18 the air nozzle 16 twice as many vortex chambers 19 , namely 16 swirl chambers 19 like the air throttle 18 the air nozzle 17 , Because the different numbers of vortex chambers 19 determine the blown air volume flows VS1, VS2, the first blown air volume flow VS1 is smaller than the second blown air volume flow VS2. Drawing not shown are air nozzles and associated air throttles of the third nozzle array 15 , Its air throttles each have even less vortex chambers than the air throttles 18 of the first nozzle field 13 , For example, the air throttles of the third nozzle field 15 four vortex chambers each. Within each of the nozzle fields 13 to 15 are the air chokes 18 preferably identical and therefore with the same number of vortex chambers 19 fitted. The air throttles of the nozzle fields 13 to 15 are assembled in sandwich construction of perforated plates.

1

machine

2

bow

3

printing unit

4

sheet delivery

5

chain conveyors

6

sheet brake

6.1

brake unit

6.2

brake unit

7

sheet pile

8th

drive shaft

9

idler pulley

10

arch support

11

brake band

12

blower

13

first nozzle array

14

second nozzle array

15

third nozzle array

16

Air nozzle (from 13 )

17

Air nozzle (from 14 )

18

air throttle

19

swirl chamber

20

die face

21

parting line

VS1

first blown air volume flow (from 16 )

VS2

second blown air volume flow (from 17 )

LR

direction

Claims (10)

Sheet brake ( 6 ) for braking bows ( 2 ) made of printing material, with circumferential brake elements ( 11 ) and at least one arch support ( 10 ) between the brake elements ( 11 ) is arranged and a blowing device ( 12 ), characterized in that the arch support ( 10 ) a first nozzle field ( 13 ) with air nozzles ( 16 ) and a second nozzle field ( 14 ) with air nozzles ( 17 ) and that the air nozzles ( 16 ) of the first nozzle field ( 13 ) are designed to generate blown air volume flows (VS2), which are smaller than blown air volume flows (VS2) of the air nozzles ( 17 ) of the second nozzle field ( 14 ) are. Sheet brake according to claim 1, characterized in that the air nozzles ( 17 ) of the second nozzle field ( 14 ) lower than the air nozzles ( 16 ) of the first nozzle field ( 13 ) are throttled. Sheet brake according to claim 1 or 2, characterized in that the air nozzles ( 16 ) of the first nozzle field ( 13 ) and the air nozzles ( 17 ) of the second nozzle field ( 14 ) labyrinthine air throttles ( 18 ) are assigned to generate the different blown air volume flows (VS1, VS2). Sheet brake according to one of claims 1 to 3, characterized in that with respect to the sheet support ( 10 ) the first nozzle field ( 13 ) central and the second nozzle field ( 14 ) is arranged more decentralized. Sheet brake according to one of claims 1 to 4, characterized in that the first nozzle field ( 13 ) from the second nozzle field ( 14 ) is surrounded annularly. Sheet brake according to one of claims 1 to 5, characterized in that the sheet support ( 10 ) a curved nozzle surface ( 20 ) having. Sheet brake according to one of claims 1 to 6, characterized in that the sheet support ( 10 ) has nozzle field-wise differing nozzle densities. Sheet brake according to one of claims 1 to 7, characterized in that the sheet support ( 10 ) and at least one further such arch support ( 10 ) in a row between the braking elements ( 11 ) are arranged. Sheet delivery, with one of claims 1 to 8 trained sheet brake. Printing machine, with a trained according to claim 9 Sheet delivery.